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authorPablo Neira Ayuso2021-03-24 02:30:55 +0100
committerDavid S. Miller2021-03-24 12:48:40 -0700
commit143490cde5669e0151dff466a7c2cf70e2884fb7 (patch)
tree0a6f602d4aade56ab7f543c0c7d8fed754170a75 /Documentation/networking/nf_flowtable.rst
parent502e84e2382d92654a2ecbc52cdbdb5a11cdcec7 (diff)
docs: nf_flowtable: update documentation with enhancements
This patch updates the flowtable documentation to describe recent enhancements: - Offload action is available after the first packets go through the classic forwarding path. - IPv4 and IPv6 are supported. Only TCP and UDP layer 4 are supported at this stage. - Tuple has been augmented to track VLAN id and PPPoE session id. - Bridge and IP forwarding integration, including bridge VLAN filtering support. - Hardware offload support. - Describe the [OFFLOAD] and [HW_OFFLOAD] tags in the conntrack table listing. - Replace 'flow offload' by 'flow add' in example rulesets (preferred syntax). - Describe existing cache limitations. Signed-off-by: Pablo Neira Ayuso <pablo@netfilter.org> Signed-off-by: David S. Miller <davem@davemloft.net>
Diffstat (limited to 'Documentation/networking/nf_flowtable.rst')
-rw-r--r--Documentation/networking/nf_flowtable.rst170
1 files changed, 143 insertions, 27 deletions
diff --git a/Documentation/networking/nf_flowtable.rst b/Documentation/networking/nf_flowtable.rst
index 6cdf9a1724b6..d87f253b9d39 100644
--- a/Documentation/networking/nf_flowtable.rst
+++ b/Documentation/networking/nf_flowtable.rst
@@ -4,35 +4,38 @@
Netfilter's flowtable infrastructure
====================================
-This documentation describes the software flowtable infrastructure available in
-Netfilter since Linux kernel 4.16.
+This documentation describes the Netfilter flowtable infrastructure which allows
+you to define a fastpath through the flowtable datapath. This infrastructure
+also provides hardware offload support. The flowtable supports for the layer 3
+IPv4 and IPv6 and the layer 4 TCP and UDP protocols.
Overview
--------
-Initial packets follow the classic forwarding path, once the flow enters the
-established state according to the conntrack semantics (ie. we have seen traffic
-in both directions), then you can decide to offload the flow to the flowtable
-from the forward chain via the 'flow offload' action available in nftables.
+Once the first packet of the flow successfully goes through the IP forwarding
+path, from the second packet on, you might decide to offload the flow to the
+flowtable through your ruleset. The flowtable infrastructure provides a rule
+action that allows you to specify when to add a flow to the flowtable.
-Packets that find an entry in the flowtable (ie. flowtable hit) are sent to the
-output netdevice via neigh_xmit(), hence, they bypass the classic forwarding
-path (the visible effect is that you do not see these packets from any of the
-netfilter hooks coming after the ingress). In case of flowtable miss, the packet
-follows the classic forward path.
+A packet that finds a matching entry in the flowtable (ie. flowtable hit) is
+transmitted to the output netdevice via neigh_xmit(), hence, packets bypass the
+classic IP forwarding path (the visible effect is that you do not see these
+packets from any of the Netfilter hooks coming after ingress). In case that
+there is no matching entry in the flowtable (ie. flowtable miss), the packet
+follows the classic IP forwarding path.
-The flowtable uses a resizable hashtable, lookups are based on the following
-7-tuple selectors: source, destination, layer 3 and layer 4 protocols, source
-and destination ports and the input interface (useful in case there are several
-conntrack zones in place).
+The flowtable uses a resizable hashtable. Lookups are based on the following
+n-tuple selectors: layer 2 protocol encapsulation (VLAN and PPPoE), layer 3
+source and destination, layer 4 source and destination ports and the input
+interface (useful in case there are several conntrack zones in place).
-Flowtables are populated via the 'flow offload' nftables action, so the user can
-selectively specify what flows are placed into the flow table. Hence, packets
-follow the classic forwarding path unless the user explicitly instruct packets
-to use this new alternative forwarding path via nftables policy.
+The 'flow add' action allows you to populate the flowtable, the user selectively
+specifies what flows are placed into the flowtable. Hence, packets follow the
+classic IP forwarding path unless the user explicitly instruct flows to use this
+new alternative forwarding path via policy.
-This is represented in Fig.1, which describes the classic forwarding path
-including the Netfilter hooks and the flowtable fastpath bypass.
+The flowtable datapath is represented in Fig.1, which describes the classic IP
+forwarding path including the Netfilter hooks and the flowtable fastpath bypass.
::
@@ -67,11 +70,13 @@ including the Netfilter hooks and the flowtable fastpath bypass.
Fig.1 Netfilter hooks and flowtable interactions
The flowtable entry also stores the NAT configuration, so all packets are
-mangled according to the NAT policy that matches the initial packets that went
-through the classic forwarding path. The TTL is decremented before calling
-neigh_xmit(). Fragmented traffic is passed up to follow the classic forwarding
-path given that the transport selectors are missing, therefore flowtable lookup
-is not possible.
+mangled according to the NAT policy that is specified from the classic IP
+forwarding path. The TTL is decremented before calling neigh_xmit(). Fragmented
+traffic is passed up to follow the classic IP forwarding path given that the
+transport header is missing, in this case, flowtable lookups are not possible.
+TCP RST and FIN packets are also passed up to the classic IP forwarding path to
+release the flow gracefully. Packets that exceed the MTU are also passed up to
+the classic forwarding path to report packet-too-big ICMP errors to the sender.
Example configuration
---------------------
@@ -85,7 +90,7 @@ flowtable and add one rule to your forward chain::
}
chain y {
type filter hook forward priority 0; policy accept;
- ip protocol tcp flow offload @f
+ ip protocol tcp flow add @f
counter packets 0 bytes 0
}
}
@@ -103,6 +108,117 @@ flow is offloaded, you will observe that the counter rule in the example above
does not get updated for the packets that are being forwarded through the
forwarding bypass.
+You can identify offloaded flows through the [OFFLOAD] tag when listing your
+connection tracking table.
+
+::
+ # conntrack -L
+ tcp 6 src=10.141.10.2 dst=192.168.10.2 sport=52728 dport=5201 src=192.168.10.2 dst=192.168.10.1 sport=5201 dport=52728 [OFFLOAD] mark=0 use=2
+
+
+Layer 2 encapsulation
+---------------------
+
+Since Linux kernel 5.13, the flowtable infrastructure discovers the real
+netdevice behind VLAN and PPPoE netdevices. The flowtable software datapath
+parses the VLAN and PPPoE layer 2 headers to extract the ethertype and the
+VLAN ID / PPPoE session ID which are used for the flowtable lookups. The
+flowtable datapath also deals with layer 2 decapsulation.
+
+You do not need to add the PPPoE and the VLAN devices to your flowtable,
+instead the real device is sufficient for the flowtable to track your flows.
+
+Bridge and IP forwarding
+------------------------
+
+Since Linux kernel 5.13, you can add bridge ports to the flowtable. The
+flowtable infrastructure discovers the topology behind the bridge device. This
+allows the flowtable to define a fastpath bypass between the bridge ports
+(represented as eth1 and eth2 in the example figure below) and the gateway
+device (represented as eth0) in your switch/router.
+
+::
+ fastpath bypass
+ .-------------------------.
+ / \
+ | IP forwarding |
+ | / \ \/
+ | br0 eth0 ..... eth0
+ . / \ *host B*
+ -> eth1 eth2
+ . *switch/router*
+ .
+ .
+ eth0
+ *host A*
+
+The flowtable infrastructure also supports for bridge VLAN filtering actions
+such as PVID and untagged. You can also stack a classic VLAN device on top of
+your bridge port.
+
+If you would like that your flowtable defines a fastpath between your bridge
+ports and your IP forwarding path, you have to add your bridge ports (as
+represented by the real netdevice) to your flowtable definition.
+
+Counters
+--------
+
+The flowtable can synchronize packet and byte counters with the existing
+connection tracking entry by specifying the counter statement in your flowtable
+definition, e.g.
+
+::
+ table inet x {
+ flowtable f {
+ hook ingress priority 0; devices = { eth0, eth1 };
+ counter
+ }
+ ...
+ }
+
+Counter support is available since Linux kernel 5.7.
+
+Hardware offload
+----------------
+
+If your network device provides hardware offload support, you can turn it on by
+means of the 'offload' flag in your flowtable definition, e.g.
+
+::
+ table inet x {
+ flowtable f {
+ hook ingress priority 0; devices = { eth0, eth1 };
+ flags offload;
+ }
+ ...
+ }
+
+There is a workqueue that adds the flows to the hardware. Note that a few
+packets might still run over the flowtable software path until the workqueue has
+a chance to offload the flow to the network device.
+
+You can identify hardware offloaded flows through the [HW_OFFLOAD] tag when
+listing your connection tracking table. Please, note that the [OFFLOAD] tag
+refers to the software offload mode, so there is a distinction between [OFFLOAD]
+which refers to the software flowtable fastpath and [HW_OFFLOAD] which refers
+to the hardware offload datapath being used by the flow.
+
+The flowtable hardware offload infrastructure also supports for the DSA
+(Distributed Switch Architecture).
+
+Limitations
+-----------
+
+The flowtable behaves like a cache. The flowtable entries might get stale if
+either the destination MAC address or the egress netdevice that is used for
+transmission changes.
+
+This might be a problem if:
+
+- You run the flowtable in software mode and you combine bridge and IP
+ forwarding in your setup.
+- Hardware offload is enabled.
+
More reading
------------